Mechanism and optimal design of a high-k dielectric conduction enhancement SOI LDMOS

Wang Xiao-Wei; Luo Xiao-Rong; Yin Chao; Fan Yuan-Hang; Zhou Kun; Fan Ye; Cai Jin-Yong; Luo Yin-Chun; Zhang Bo; Li Zhao-Ji

doi:10.7498/aps.62.237301

Abstract

A high-k dielectric conduction enhancement SOI LDMOS is proposed and investigated by simulation. The high-k dielectric pillars are located at sidewalls of the drift region. The high-k dielectric assists the self-adapted depletion in the drift region, reshapes the electric field distribution, and makes the three-dimensional RESURF effect realized in a high-voltage blocking state. Dependences of the breakdown voltage (VB) and the specific on-resistance (Ron,sp) on device parameters are exhibited using three-dimensional simulation. Simulation results show that the proposed structure increases VB by 16%–18% and decreases Ron.sp by 13%–20%, compared with the conventional super-junction SOI LDMOS. Furthermore, the charge-imbalance caused by the substrate-assisted depletion effect is alleviated.

Keywords:

Authors and contacts

1.
College of Microelectronic and Solid-State electronic, University of Electronic Science & Technology, Chengdu 610054, China
Funds: Project supported by the National Natural Science Foundation of China (Grant No. 61176069), China Postdoctoral Science Foundation (Grant No. 2012T50771), and the Program for New Century Excellent Talents in University of Ministry of Education of China (Grant No. NCET-11-0062).

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Cited By

[1]	Zhang B, Luo X R, Li Z J 2010 Chin. Phys. B 19 037303
[2]	Zhang B, Hu S D, Li Z J 2009 Chin. Phys. B 18 319
[3]	Li Z J, Zhang B, Li Q 2007 Acta Phys. Sin. 56 6660 (in Chinese) [李肇基, 张波, 李琦 2007 物理学报 56 6660]
[4]	Chen X B, Mawby P A, Board K, Salama C A T 1998 Microelectron J. 29 1005
[5]	Nassif-Khalil S G, Salama C A T 2002 ISPSD 1 81
[6]	Pathirana G P V, Udrea F, Ng R, Garner D M, Amaratunga G A J 2003 ISPSD 1 278
[7]	Xu S, Gan K P, Samudra G S, Liang Y C, O J K 2000 IEEE Trans Electron Devices 47 1980
[8]	Amberetu M A, Salama C A T 2002 ISPSD 1 101
[9]	Nassif-Khalil S G, Salama C A T 2003 IEEE Tran. Electron Devices 50 1385
[10]	Nassif-Khalil S G, Salama C A T 2003 ISPSD 1 228
[11]	Chen Y, Liang Y C, Samudra G S 2006 IEEE Industrial Electronics 32 2746
[12]	Chen X 2007 U S Patent 7230310B2 1 1
[13]	Luo X R, Jiang Y H, Zhou K, Wang P, Wang X W, Wang Q, Yao G L, Zhang B, Li Z J 2012 IEEE Electron Device Letters 33 1042
[14]	Luo X R, Cai J Y, Fan Y, Fan Y H, Wang X W, Wei J, Jang Y H, Zhou K, Yin C, Zhang B, Li Z J, Hu G Y 2013 IEEE Electron Device Letters 60 2840
[15]	Pontes M, Lee E J H, Leite E R, Longo E, Varela J A 2000 J. Mater Sci. 35 4783
[16]	Wang Z, Kugler V, Helmersson U, Konofaos N, Evangelou E K, Nakao S, Jin P 2001 Appl Phy. Lett. 79 1513

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Vol. 62, Issue 23 - 2013-12-05

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